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RecQ helicase

January 01, 1970

RecQ helicase is a family of helicase enzymes initially found in Escherichia coli[1] that has been shown to be important in genome maintenance.[2][3][4] They function through catalyzing the reaction ATP + H2O → ADP + P and thus driving the unwinding of paired DNA and translocating in the 3' to 5' direction. These enzymes can also drive the reaction NTP + H2O → NDP + P to drive the unwinding of either DNA or RNA.

Bloom syndrome
Identifiers
SymbolBLM
NCBI gene641
HGNC1058
OMIM604610
RefSeqNM_000057
UniProtP54132
Other data
LocusChr. 15 [1]
Search for
StructuresSwiss-model
DomainsInterPro
RecQ protein-like 4
Identifiers
SymbolRECQL4
NCBI gene9401
HGNC9949
OMIM603780
RefSeqNM_004260
UniProtO94761
Other data
LocusChr. 8 q24.3
Search for
StructuresSwiss-model
DomainsInterPro
RecQ protein-like 5
Identifiers
SymbolRECQL5
NCBI gene9400
HGNC9950
OMIM603781
RefSeqNM_004259
UniProtO94762
Other data
LocusChr. 17 q25
Search for
StructuresSwiss-model
DomainsInterPro
RMI1, RecQ mediated genome instability 1
Identifiers
SymbolRMI1
Alt. symbolsC9orf76
NCBI gene80010
HGNC25764
OMIM610404
RefSeqNM_024945
UniProtQ9H9A7
Other data
LocusChr. 9 q22.1
Search for
StructuresSwiss-model
DomainsInterPro
Werner syndrome
Identifiers
SymbolWRN
NCBI gene7486
HGNC12791
OMIM604611
RefSeqNM_000553
UniProtQ14191
Other data
LocusChr. 8 p
Search for
StructuresSwiss-model
DomainsInterPro

Function edit

In prokaryotes RecQ is necessary for plasmid recombination and DNA repair from UV-light, free radicals, and alkylating agents. This protein can also reverse damage from replication errors. In eukaryotes, replication does not proceed normally in the absence of RecQ proteins, which also function in aging, silencing, recombination and DNA repair.

Structure edit

RecQ family members share three regions of conserved protein sequence referred to as the:

  • N-terminal – Helicase
  • middle – RecQ-conserved (RecQ-Ct) and
  • C-terminal – Helicase-and-RNase-D C-terminal (HRDC) domains.

The removal of the N-terminal residues (Helicase and, RecQ-Ct domains) impairs both helicase and ATPase activity but has no effect on the binding ability of RecQ implying that the N-terminus functions as the catalytic end. Truncations of the C-terminus (HRDC domain) compromise the binding ability of RecQ but not the catalytic function. The importance of RecQ in cellular functions is exemplified by human diseases, which all lead to genomic instability and a predisposition to cancer.

Clinical significance edit

There are at least five human RecQ genes; and mutations in three human RecQ genes are implicated in heritable human diseases: WRN gene in Werner syndrome (WS), BLM gene in Bloom syndrome (BS), and RECQL4 in Rothmund–Thomson syndrome.[5] These syndromes are characterized by premature aging, and can give rise to the diseases of cancer, type 2 diabetes, osteoporosis, and atherosclerosis, which are commonly found in old age. These diseases are associated with high incidence of chromosomal abnormalities, including chromosome breaks, complex rearrangements, deletions and translocations, site specific mutations, and in particular sister chromatid exchanges (more common in BS) that are believed to be caused by a high level of somatic recombination.

Mechanism edit

The proper function of RecQ helicases requires the specific interaction with topoisomerase III (Top 3). Top 3 changes the topological status of DNA by binding and cleaving single stranded DNA and passing either a single stranded or a double stranded DNA segment through the transient break and finally re-ligating the break. The interaction of RecQ helicase with topoisomerase III at the N-terminal region is involved in the suppression of spontaneous and damage induced recombination and the absence of this interaction results in a lethal or very severe phenotype. The emerging picture clearly is that RecQ helicases in concert with Top 3 are involved in maintaining genomic stability and integrity by controlling recombination events, and repairing DNA damage in the G2-phase of the cell cycle. The importance of RecQ for genomic integrity is exemplified by the diseases that arise as a consequence of mutations or malfunctions in RecQ helicases; thus it is crucial that RecQ is present and functional to ensure proper human growth and development.

WRN helicase edit

The Werner syndrome ATP-dependent helicase (WRN helicase) is unusual among RecQ DNA family helicases in having an additional exonuclease activity. WRN interacts with DNA-PKcs and the Ku protein complex. This observation, combined with evidence that WRN deficient cells produce extensive deletions at sites of joining of non-homologous DNA ends, suggests a role for WRN protein in the DNA repair process of non-homologous end joining (NHEJ).[6] WRN also physically interacts with the major NHEJ factor X4L4 (XRCC4-DNA ligase 4 complex).[7] X4L4 stimulates WRN exonuclease activity that likely facilitates DNA end processing prior to final ligation by X4L4.[7]

WRN also appears to play a role in resolving recombination intermediate structures during homologous recombinational repair (HRR) of DNA double-strand breaks.[6]

WRN participates in a complex with RAD51, RAD54, RAD54B and ATR proteins in carrying out the recombination step during inter-strand DNA cross-link repair.[8]

Evidence was presented that WRN plays a direct role in the repair of methylation induced DNA damage. The process likely involves the helicase and exonuclease activities of WRN that operate together with DNA polymerase beta in long patch base excision repair.[9]

WRN was found to have a specific role in preventing or repairing DNA damages resulting from chronic oxidative stress, particularly in slowly replicating cells.[10] This finding suggested that WRN may be important in dealing with oxidative DNA damages that underlie normal aging[10] (see DNA damage theory of aging).

BLM helicase edit

Cells from humans with Bloom syndrome are sensitive to DNA damaging agents such as UV and methyl methanesulfonate[11] indicating deficient DNA repair capability.

The budding yeast Saccharomyces cerevisiae encodes an ortholog of the Bloom syndrome (BLM) protein that is designated Sgs1 (Small growth suppressor 1). Sgs1(BLM) is a helicase that functions in homologous recombinational repair of DNA double-strand breaks. The Sgs1(BLM) helicase appears to be a central regulator of most of the recombination events that occur during S. cerevisiae meiosis.[12] During normal meiosis Sgs1(BLM) is responsible for directing recombination towards the alternate formation of either early non-crossovers or Holliday junction joint molecules, the latter being subsequently resolved as crossovers.[12]

In the plant Arabidopsis thaliana, homologs of the Sgs1(BLM) helicase act as major barriers to meiotic crossover formation.[13] These helicases are thought to displace the invading strand allowing its annealing with the other 3’overhang end of the double-strand break, leading to non-crossover recombinant formation by a process called synthesis-dependent strand annealing (SDSA) (see Wikipedia article “Genetic recombination”). It is estimated that only about 5% of double-strand breaks are repaired by crossover recombination. Sequela-Arnaud et al.[13] suggested that crossover numbers are restricted because of the long-term costs of crossover recombination, that is, the breaking up of favorable genetic combinations of alleles built up by past natural selection.

RECQL4 helicase edit

In humans, individuals with Rothmund–Thomson syndrome, and carrying the RECQL4 germline mutation, have several clinical features of accelerated aging. These features include atrophic skin and pigment changes, alopecia, osteopenia, cataracts and an increased incidence of cancer.[14] RECQL4 mutant mice also show features of accelerated aging.[15]

RECQL4 has a crucial role in DNA end resection that is the initial step required for homologous recombination (HR)-dependent double-strand break repair.[16] When RECQL4 is depleted, HR-mediated repair and 5’ end resection are severely reduced in vivo. RECQL4 also appears to be necessary for other forms of DNA repair including non-homologous end joining, nucleotide excision repair and base excision repair.[14] The association of deficient RECQL4 mediated DNA repair with accelerated aging is consistent with the DNA damage theory of aging.

See also edit

References edit

  1. ^ Bernstein DA, Keck JL (June 2003). "Domain mapping of Escherichia coli RecQ defines the roles of conserved N- and C-terminal regions in the RecQ family". Nucleic Acids Res. 31 (11): 2778–85. doi:10.1093/nar/gkg376. PMC 156711. PMID 12771204.
  2. ^ Cobb JA, Bjergbaek L, Gasser SM (October 2002). "RecQ helicases: at the heart of genetic stability". FEBS Lett. 529 (1): 43–8. doi:10.1016/S0014-5793(02)03269-6. PMID 12354611. S2CID 19451131.
  3. ^ Kaneko H, Fukao T, Kondo N (2004). "The function of RecQ helicase gene family (especially BLM) in DNA recombination and joining". Adv. Biophys. 38: 45–64. doi:10.1016/S0065-227X(04)80061-3. PMID 15493327.
  4. ^ Ouyang KJ, Woo LL, Ellis NA (2008). "Homologous recombination and maintenance of genome integrity: cancer and aging through the prism of human RecQ helicases". Mech. Ageing Dev. 129 (7–8): 425–40. doi:10.1016/j.mad.2008.03.003. PMID 18430459. S2CID 6804631.
  5. ^ Hanada K, Hickson ID (September 2007). "Molecular genetics of RecQ helicase disorders". Cell. Mol. Life Sci. 64 (17): 2306–22. doi:10.1007/s00018-007-7121-z. PMID 17571213. S2CID 29287970.
  6. ^ a b Thompson LH, Schild D (2002). "Recombinational DNA repair and human disease". Mutat. Res. 509 (1–2): 49–78. doi:10.1016/s0027-5107(02)00224-5. PMID 12427531.
  7. ^ a b Kusumoto R, Dawut L, Marchetti C, Wan Lee J, Vindigni A, Ramsden D, Bohr VA (2008). "Werner protein cooperates with the XRCC4-DNA ligase IV complex in end-processing". Biochemistry. 47 (28): 7548–56. doi:10.1021/bi702325t. PMC 2572716. PMID 18558713.
  8. ^ Otterlei M, Bruheim P, Ahn B, Bussen W, Karmakar P, Baynton K, Bohr VA (2006). "Werner syndrome protein participates in a complex with RAD51, RAD54, RAD54B and ATR in response to ICL-induced replication arrest". J. Cell Sci. 119 (Pt 24): 5137–46. doi:10.1242/jcs.03291. PMID 17118963.
  9. ^ Harrigan JA, Wilson DM, Prasad R, Opresko PL, Beck G, May A, Wilson SH, Bohr VA (2006). "The Werner syndrome protein operates in base excision repair and cooperates with DNA polymerase beta". Nucleic Acids Res. 34 (2): 745–54. doi:10.1093/nar/gkj475. PMC 1356534. PMID 16449207.
  10. ^ a b Szekely AM, Bleichert F, Nümann A, Van Komen S, Manasanch E, Ben Nasr A, Canaan A, Weissman SM (2005). "Werner protein protects nonproliferating cells from oxidative DNA damage". Mol. Cell. Biol. 25 (23): 10492–506. doi:10.1128/MCB.25.23.10492-10506.2005. PMC 1291253. PMID 16287861.
  11. ^ So S, Adachi N, Lieber MR, Koyama H (2004). "Genetic interactions between BLM and DNA ligase IV in human cells". J. Biol. Chem. 279 (53): 55433–42. doi:10.1074/jbc.M409827200. PMID 15509577.
  12. ^ a b De Muyt A, Jessop L, Kolar E, Sourirajan A, Chen J, Dayani Y, Lichten M (2012). "BLM helicase ortholog Sgs1 is a central regulator of meiotic recombination intermediate metabolism". Mol. Cell. 46 (1): 43–53. doi:10.1016/j.molcel.2012.02.020. PMC 3328772. PMID 22500736.
  13. ^ a b Séguéla-Arnaud M, Crismani W, Larchevêque C, Mazel J, Froger N, Choinard S, Lemhemdi A, Macaisne N, Van Leene J, Gevaert K, De Jaeger G, Chelysheva L, Mercier R (2015). "Multiple mechanisms limit meiotic crossovers: TOP3α and two BLM homologs antagonize crossovers in parallel to FANCM". Proc. Natl. Acad. Sci. U.S.A. 112 (15): 4713–8. Bibcode:2015PNAS..112.4713S. doi:10.1073/pnas.1423107112. PMC 4403193. PMID 25825745.
  14. ^ a b Lu L, Jin W, Wang LL (2017). "Aging in Rothmund-Thomson syndrome and related RECQL4 genetic disorders". Ageing Res. Rev. 33: 30–35. doi:10.1016/j.arr.2016.06.002. PMID 27287744. S2CID 28321025.
  15. ^ Lu H, Fang EF, Sykora P, Kulikowicz T, Zhang Y, Becker KG, Croteau DL, Bohr VA (2014). "Senescence induced by RECQL4 dysfunction contributes to Rothmund-Thomson syndrome features in mice". Cell Death Dis. 5 (5): e1226. doi:10.1038/cddis.2014.168. PMC 4047874. PMID 24832598.
  16. ^ Lu H, Shamanna RA, Keijzers G, Anand R, Rasmussen LJ, Cejka P, Croteau DL, Bohr VA (2016). "RECQL4 Promotes DNA End Resection in Repair of DNA Double-Strand Breaks". Cell Rep. 16 (1): 161–73. doi:10.1016/j.celrep.2016.05.079. PMC 5576896. PMID 27320928.

Further reading edit

  • Skouboe C, Bjergbaek L, Andersen AH (2005). "Genome instability as a cause of ageing and cancer: Implications of RecQ helicases". Signal Transduction. 5 (3): 142–151. doi:10.1002/sita.200400052.
  • Laursen LV, Bjergbaek L, Murray JM, Andersen AH (2003). "RecQ helicases and topoisomerase III in cancer and aging". Biogerontology. 4 (5): 275–87. doi:10.1023/A:1026218513772. PMID 14618025. S2CID 6242136.

External links edit

  • RecQ Helicases 2004-11-02 at the Wayback Machine, introduction at UNC's Sekelsky Lab.
  • BLM gene encodes a RecQ Helicase, description of the gene

January 01, 1970
recq, helicase, family, helicase, enzymes, initially, found, escherichia, coli, that, been, shown, important, genome, maintenance, they, function, through, catalyzing, reaction, thus, driving, unwinding, paired, translocating, direction, these, enzymes, also, . RecQ helicase is a family of helicase enzymes initially found in Escherichia coli 1 that has been shown to be important in genome maintenance 2 3 4 They function through catalyzing the reaction ATP H2O ADP P and thus driving the unwinding of paired DNA and translocating in the 3 to 5 direction These enzymes can also drive the reaction NTP H2O NDP P to drive the unwinding of either DNA or RNA Bloom syndromeIdentifiersSymbolBLMNCBI gene641HGNC1058OMIM604610RefSeqNM 000057UniProtP54132Other dataLocusChr 15 1 Search forStructuresSwiss modelDomainsInterPro RecQ protein like 4IdentifiersSymbolRECQL4NCBI gene9401HGNC9949OMIM603780RefSeqNM 004260UniProtO94761Other dataLocusChr 8 q24 3Search forStructuresSwiss modelDomainsInterPro RecQ protein like 5IdentifiersSymbolRECQL5NCBI gene9400HGNC9950OMIM603781RefSeqNM 004259UniProtO94762Other dataLocusChr 17 q25Search forStructuresSwiss modelDomainsInterPro RMI1 RecQ mediated genome instability 1IdentifiersSymbolRMI1Alt symbolsC9orf76NCBI gene80010HGNC25764OMIM610404RefSeqNM 024945UniProtQ9H9A7Other dataLocusChr 9 q22 1Search forStructuresSwiss modelDomainsInterPro Werner syndromeIdentifiersSymbolWRNNCBI gene7486HGNC12791OMIM604611RefSeqNM 000553UniProtQ14191Other dataLocusChr 8 pSearch forStructuresSwiss modelDomainsInterPro Contents 1 Function 2 Structure 3 Clinical significance 4 Mechanism 4 1 WRN helicase 4 2 BLM helicase 4 3 RECQL4 helicase 5 See also 6 References 7 Further reading 8 External linksFunction editIn prokaryotes RecQ is necessary for plasmid recombination and DNA repair from UV light free radicals and alkylating agents This protein can also reverse damage from replication errors In eukaryotes replication does not proceed normally in the absence of RecQ proteins which also function in aging silencing recombination and DNA repair Structure editRecQ family members share three regions of conserved protein sequence referred to as the N terminal Helicase middle RecQ conserved RecQ Ct and C terminal Helicase and RNase D C terminal HRDC domains The removal of the N terminal residues Helicase and RecQ Ct domains impairs both helicase and ATPase activity but has no effect on the binding ability of RecQ implying that the N terminus functions as the catalytic end Truncations of the C terminus HRDC domain compromise the binding ability of RecQ but not the catalytic function The importance of RecQ in cellular functions is exemplified by human diseases which all lead to genomic instability and a predisposition to cancer Clinical significance editThere are at least five human RecQ genes and mutations in three human RecQ genes are implicated in heritable human diseases WRN gene in Werner syndrome WS BLM gene in Bloom syndrome BS and RECQL4 in Rothmund Thomson syndrome 5 These syndromes are characterized by premature aging and can give rise to the diseases of cancer type 2 diabetes osteoporosis and atherosclerosis which are commonly found in old age These diseases are associated with high incidence of chromosomal abnormalities including chromosome breaks complex rearrangements deletions and translocations site specific mutations and in particular sister chromatid exchanges more common in BS that are believed to be caused by a high level of somatic recombination Mechanism editThe proper function of RecQ helicases requires the specific interaction with topoisomerase III Top 3 Top 3 changes the topological status of DNA by binding and cleaving single stranded DNA and passing either a single stranded or a double stranded DNA segment through the transient break and finally re ligating the break The interaction of RecQ helicase with topoisomerase III at the N terminal region is involved in the suppression of spontaneous and damage induced recombination and the absence of this interaction results in a lethal or very severe phenotype The emerging picture clearly is that RecQ helicases in concert with Top 3 are involved in maintaining genomic stability and integrity by controlling recombination events and repairing DNA damage in the G2 phase of the cell cycle The importance of RecQ for genomic integrity is exemplified by the diseases that arise as a consequence of mutations or malfunctions in RecQ helicases thus it is crucial that RecQ is present and functional to ensure proper human growth and development WRN helicase edit The Werner syndrome ATP dependent helicase WRN helicase is unusual among RecQ DNA family helicases in having an additional exonuclease activity WRN interacts with DNA PKcs and the Ku protein complex This observation combined with evidence that WRN deficient cells produce extensive deletions at sites of joining of non homologous DNA ends suggests a role for WRN protein in the DNA repair process of non homologous end joining NHEJ 6 WRN also physically interacts with the major NHEJ factor X4L4 XRCC4 DNA ligase 4 complex 7 X4L4 stimulates WRN exonuclease activity that likely facilitates DNA end processing prior to final ligation by X4L4 7 WRN also appears to play a role in resolving recombination intermediate structures during homologous recombinational repair HRR of DNA double strand breaks 6 WRN participates in a complex with RAD51 RAD54 RAD54B and ATR proteins in carrying out the recombination step during inter strand DNA cross link repair 8 Evidence was presented that WRN plays a direct role in the repair of methylation induced DNA damage The process likely involves the helicase and exonuclease activities of WRN that operate together with DNA polymerase beta in long patch base excision repair 9 WRN was found to have a specific role in preventing or repairing DNA damages resulting from chronic oxidative stress particularly in slowly replicating cells 10 This finding suggested that WRN may be important in dealing with oxidative DNA damages that underlie normal aging 10 see DNA damage theory of aging BLM helicase edit Cells from humans with Bloom syndrome are sensitive to DNA damaging agents such as UV and methyl methanesulfonate 11 indicating deficient DNA repair capability The budding yeast Saccharomyces cerevisiae encodes an ortholog of the Bloom syndrome BLM protein that is designated Sgs1 Small growth suppressor 1 Sgs1 BLM is a helicase that functions in homologous recombinational repair of DNA double strand breaks The Sgs1 BLM helicase appears to be a central regulator of most of the recombination events that occur during S cerevisiae meiosis 12 During normal meiosis Sgs1 BLM is responsible for directing recombination towards the alternate formation of either early non crossovers or Holliday junction joint molecules the latter being subsequently resolved as crossovers 12 In the plant Arabidopsis thaliana homologs of the Sgs1 BLM helicase act as major barriers to meiotic crossover formation 13 These helicases are thought to displace the invading strand allowing its annealing with the other 3 overhang end of the double strand break leading to non crossover recombinant formation by a process called synthesis dependent strand annealing SDSA see Wikipedia article Genetic recombination It is estimated that only about 5 of double strand breaks are repaired by crossover recombination Sequela Arnaud et al 13 suggested that crossover numbers are restricted because of the long term costs of crossover recombination that is the breaking up of favorable genetic combinations of alleles built up by past natural selection RECQL4 helicase edit In humans individuals with Rothmund Thomson syndrome and carrying the RECQL4 germline mutation have several clinical features of accelerated aging These features include atrophic skin and pigment changes alopecia osteopenia cataracts and an increased incidence of cancer 14 RECQL4 mutant mice also show features of accelerated aging 15 RECQL4 has a crucial role in DNA end resection that is the initial step required for homologous recombination HR dependent double strand break repair 16 When RECQL4 is depleted HR mediated repair and 5 end resection are severely reduced in vivo RECQL4 also appears to be necessary for other forms of DNA repair including non homologous end joining nucleotide excision repair and base excision repair 14 The association of deficient RECQL4 mediated DNA repair with accelerated aging is consistent with the DNA damage theory of aging See also editBloom syndromeReferences edit Bernstein DA Keck JL June 2003 Domain mapping of Escherichia coli RecQ defines the roles of conserved N and C terminal regions in the RecQ family Nucleic Acids Res 31 11 2778 85 doi 10 1093 nar gkg376 PMC 156711 PMID 12771204 Cobb JA Bjergbaek L Gasser SM October 2002 RecQ helicases at the heart of genetic stability FEBS Lett 529 1 43 8 doi 10 1016 S0014 5793 02 03269 6 PMID 12354611 S2CID 19451131 Kaneko H Fukao T Kondo N 2004 The function of RecQ helicase gene family especially BLM in DNA recombination and joining Adv Biophys 38 45 64 doi 10 1016 S0065 227X 04 80061 3 PMID 15493327 Ouyang KJ Woo LL Ellis NA 2008 Homologous recombination and maintenance of genome integrity cancer and aging through the prism of human RecQ helicases Mech Ageing Dev 129 7 8 425 40 doi 10 1016 j mad 2008 03 003 PMID 18430459 S2CID 6804631 Hanada K Hickson ID September 2007 Molecular genetics of RecQ helicase disorders Cell Mol Life Sci 64 17 2306 22 doi 10 1007 s00018 007 7121 z PMID 17571213 S2CID 29287970 a b Thompson LH Schild D 2002 Recombinational DNA repair and human disease Mutat Res 509 1 2 49 78 doi 10 1016 s0027 5107 02 00224 5 PMID 12427531 a b Kusumoto R Dawut L Marchetti C Wan Lee J Vindigni A Ramsden D Bohr VA 2008 Werner protein cooperates with the XRCC4 DNA ligase IV complex in end processing Biochemistry 47 28 7548 56 doi 10 1021 bi702325t PMC 2572716 PMID 18558713 Otterlei M Bruheim P Ahn B Bussen W Karmakar P Baynton K Bohr VA 2006 Werner syndrome protein participates in a complex with RAD51 RAD54 RAD54B and ATR in response to ICL induced replication arrest J Cell Sci 119 Pt 24 5137 46 doi 10 1242 jcs 03291 PMID 17118963 Harrigan JA Wilson DM Prasad R Opresko PL Beck G May A Wilson SH Bohr VA 2006 The Werner syndrome protein operates in base excision repair and cooperates with DNA polymerase beta Nucleic Acids Res 34 2 745 54 doi 10 1093 nar gkj475 PMC 1356534 PMID 16449207 a b Szekely AM Bleichert F Numann A Van Komen S Manasanch E Ben Nasr A Canaan A Weissman SM 2005 Werner protein protects nonproliferating cells from oxidative DNA damage Mol Cell Biol 25 23 10492 506 doi 10 1128 MCB 25 23 10492 10506 2005 PMC 1291253 PMID 16287861 So S Adachi N Lieber MR Koyama H 2004 Genetic interactions between BLM and DNA ligase IV in human cells J Biol Chem 279 53 55433 42 doi 10 1074 jbc M409827200 PMID 15509577 a b De Muyt A Jessop L Kolar E Sourirajan A Chen J Dayani Y Lichten M 2012 BLM helicase ortholog Sgs1 is a central regulator of meiotic recombination intermediate metabolism Mol Cell 46 1 43 53 doi 10 1016 j molcel 2012 02 020 PMC 3328772 PMID 22500736 a b Seguela Arnaud M Crismani W Larcheveque C Mazel J Froger N Choinard S Lemhemdi A Macaisne N Van Leene J Gevaert K De Jaeger G Chelysheva L Mercier R 2015 Multiple mechanisms limit meiotic crossovers TOP3a and two BLM homologs antagonize crossovers in parallel to FANCM Proc Natl Acad Sci U S A 112 15 4713 8 Bibcode 2015PNAS 112 4713S doi 10 1073 pnas 1423107112 PMC 4403193 PMID 25825745 a b Lu L Jin W Wang LL 2017 Aging in Rothmund Thomson syndrome and related RECQL4 genetic disorders Ageing Res Rev 33 30 35 doi 10 1016 j arr 2016 06 002 PMID 27287744 S2CID 28321025 Lu H Fang EF Sykora P Kulikowicz T Zhang Y Becker KG Croteau DL Bohr VA 2014 Senescence induced by RECQL4 dysfunction contributes to Rothmund Thomson syndrome features in mice Cell Death Dis 5 5 e1226 doi 10 1038 cddis 2014 168 PMC 4047874 PMID 24832598 Lu H Shamanna RA Keijzers G Anand R Rasmussen LJ Cejka P Croteau DL Bohr VA 2016 RECQL4 Promotes DNA End Resection in Repair of DNA Double Strand Breaks Cell Rep 16 1 161 73 doi 10 1016 j celrep 2016 05 079 PMC 5576896 PMID 27320928 Further reading editSkouboe C Bjergbaek L Andersen AH 2005 Genome instability as a cause of ageing and cancer Implications of RecQ helicases Signal Transduction 5 3 142 151 doi 10 1002 sita 200400052 Laursen LV Bjergbaek L Murray JM Andersen AH 2003 RecQ helicases and topoisomerase III in cancer and aging Biogerontology 4 5 275 87 doi 10 1023 A 1026218513772 PMID 14618025 S2CID 6242136 External links editRecQ Helicases Archived 2004 11 02 at the Wayback Machine introduction at UNC s Sekelsky Lab BLM gene encodes a RecQ Helicase description of the gene Portal nbsp Biology Retrieved from https en wikipedia org w index php title RecQ helicase amp oldid 1116889000, wikipedia, wiki, book, books, library,

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